Device employable in different circuit configurations using parallel wiring harnesses, a HVAC system employing the device and a method of manufacturing a HVAC unit

ABSTRACT

A HVAC unit manufacturing method and a HVAC system are disclosed herein. In one embodiment, the HVAC system includes: a controller having control board terminals, a parallel wiring harness having a first and a second connection header, the first connection header coupled to the control board terminals, and a switch having terminals. The terminals of the switch including: a pair of functional terminals configured to indicate a status of the switch and a pair of jumpered terminals independent of the pair of functional terminals and internally connected together within the switch, wherein designated combinations of the terminals indicate a circuit configuration for employing the switch in the HVAC system with each of the terminals having a particular design that dictates a specific corresponding connection header be used for each of the designated combinations, wherein a single one of the designated combinations of the terminals corresponds to the second connection header.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/573,047, filed on Dec. 17, 2014. U.S. patent application Ser. No.14/573,047 is a divisional of U.S. patent application Ser. No.12/985,129, filed on Jan. 5, 2011, which is now U.S. Pat. No. 8,939,789.U.S. patent application Ser. No. 14/573,047 and U.S. patent applicationSer. No. 12/985,129 are incorporated herein by reference.

TECHNICAL FIELD

This application is directed, in general, to electrical devices andparallel wiring connectors.

BACKGROUND

Heating, Ventilating and Air Conditioning (HVAC) systems use multipleelectrical devices that are connected together to perform a desiredfunction. These electrical devices may be common devices that areobtained from third parties and used by various HVAC manufacturers intheir particular HVAC units. As such, these electrical devices may havegeneric terminals, such as spade connectors.

With the generic terminals, the various electrical devices are oftenconnected together using point-to-point wiring. Point-to-point wiring,however, can be labor intensive since individual harnesses are typicallymade for each particular connection. Point-to-point harnesses can alsobe more prone to errors. For example, with point-to-point wiring, wirescan be connected in multiple positions and can even fit on wrongcomponents. Additionally, with point-to-point harnesses, the harnessescan not be pretested. Instead, they are only tested after installed inthe different HVAC units.

As such, it is essentially impossible to mistake proof the wiring duringmanufacturing of HVAC units when using point-to-point wiring. This canlead to incorrect connections of the wires during manufacturing andassembly. Accordingly, troubleshooting can also be difficult whenemploying point-to-point wiring with multiple components since faultsmay be due to wiring problems instead of faulty components. Thus, inaddition to problems in manufacturing, it is also easier for the fieldto make incorrect wiring changes with point-to-point wiring. This canlead to errors in servicing a HVAC unit, which in turn can lead to amalfunction in the operation of the unit.

SUMMARY

One aspect provides a method of manufacturing an HVAC unit. In oneembodiment, the method includes: (1) connecting a first device to asecond device having multiple terminals employing a first parallelwiring harness, the multiple terminals including a pair of functionalterminals connected across a contact of the second device and a pair ofjumpered terminals independent of the pair of functional terminals andinternally connected together, wherein designated combinations of theterminals indicate a circuit configuration for the electrical devicewith each of the terminals having a particular design that dictates aspecific corresponding connection header be used for each of thedesignated combinations and (2) connecting the second device to a thirddevice employing a second parallel wiring harness, wherein the thirddevice is a same device as the second device and the first parallelwiring harness has a first connection header configured to connect toone of the designated combinations to implement a particular circuitconfiguration.

In another aspect, an HVAC system is disclosed. In one embodiment, theHVAC system includes: (1) a controller having control board terminals,(2) a parallel wiring harness having a first and a second connectionheader, the first connection header coupled to the control boardterminals, and (3) a switch having terminals. The terminals of theswitch including: (3A) a pair of functional terminals configured toindicate a status of the switch and (3B) a pair of jumpered terminalsindependent of the pair of functional terminals and internally connectedtogether within the switch, wherein designated combinations of theterminals indicate a circuit configuration for employing the switch inthe HVAC system with each of the terminals having a particular designthat dictates a specific corresponding connection header be used foreach of the designated combinations, wherein a single one of thedesignated combinations of the terminals corresponds to the secondconnection header.

BRIEF DESCRIPTION

Reference is now made to the following descriptions taken in conjunctionwith the accompanying drawings, in which:

FIG. 1 illustrates a block diagram of an embodiment of an HVAC systemconstructed according to the principles of the disclosure;

FIG. 2 illustrates a diagram of an embodiment of a single electricaldevice employed in a circuit and constructed according to the principlesof the disclosure;

FIG. 3 illustrates a diagram of two electrical devices as illustrated inFIG. 2 connected in series;

FIG. 4 illustrates a connection diagram of another embodiment of asingle electrical device constructed according to the principles of thedisclosure that has terminals which are keyed for designated matinginterfaces;

FIG. 5 illustrates a connection diagram of a circuit configurationhaving two of the electrical devices of FIG. 4 coupled in series;

FIGS. 6A, 6B and 6C illustrate schematic diagrams of yet anotherembodiment of an electrical device constructed according to theprinciples of the disclosure;

FIG. 7A illustrates various circuit configurations and FIGS. 7B, 7C and7D illustrate schematic diagrams of embodiments of a switch constructedaccording to the principles of the disclosure and employed in thevarious configurations of FIG. 7A.

FIG. 8 illustrates a flow diagram of an embodiment of a method ofmanufacturing an HVAC unit carried out according to the principles ofthe disclosure.

DETAILED DESCRIPTION

Parallel wiring harnesses have wires that are parallel from one end ofthe harness to the other without crisscrossed circuits or single endedwires. Even with generic terminals, parallel wiring harnesses may beused with some devices when these devices are used individually in acircuit (i.e., not coupled to at least another one of the devices eitherin series, in parallel or as a branch circuit). Nevertheless, whenmultiple of the same devices are employed in a circuit, the parallelwiring harnesses may not be applicable. Instead, point-to-point wiringis used when multiple of the same electrical devices, such as pressureswitches or temperature limit switches, are connected in series.

This disclosure provides electrical devices that are constructed for usewith parallel wiring harnesses when used in multiple circuitconfigurations. Thus, parallel wiring harnesses can be used to couplethe disclosed devices when used individually in a circuit and also whenthe same type of devices are used in series, in parallel or in a branchcircuit. Accordingly, the disclosed devices can be used in differentcircuit configurations and still employ parallel wiring harnesses. Thisallows parallel wiring harnesses to be made for various circuitconfigurations and pretested before use. As such, the number of wiringerrors in, for example, HVAC units, can be reduced.

In many HVAC applications, various components have to be electricallyconnected or serviced in the field. In such instances, the servicetechnician must make the appropriate connections when either assemblingthe HVAC system or servicing an in-place unit. Often in HVAC systems,such as HVAC rooftop units, the wiring schemes can be very complicated,which increases the chance of a wrong electrical connection being made.The disclosed electrical devices are designed to reduce the number oferroneous connections being made during manufacturing, installation orservicing.

The disclosed electrical devices include functional terminals that arecoupled across a contact of the electrical devices. The contact may be anormally opened contact or a normally closed contact. The contact mayindicate operation or non-operation of the electrical devices. Theelectrical devices, for example, may be switches, such as pressureswitches or limit switches.

Additionally, the disclosed electrical devices include a pair ofjumpered terminals that are independent of the functional terminals andare internally connected together inside of the electrical device. Thejumpered terminals allow parallel wiring connectors to be coupled to theelectrical device regardless if the electrical device is usedindividually in a circuit or with another electrical device in a circuit(e.g., two of the electrical devices in series). Thus, parallel wiringharnesses can be used with a single device or with multiple of the samedevices in different circuit configurations. Additionally, the terminalsof the disclosed electrical devices are designed for correspondingconnection headers to dictate the circuit configuration in which theelectrical device is used. Accordingly, designated combinations of theterminals indicate a circuit configuration for the electrical devicewith each of the terminals having a particular design that dictates aspecific corresponding connection header be used for each of thedesignated combinations. The connection headers, therefore, areconfigured to correspond to designated terminals of the disclosedelectrical devices for particular circuit configurations. As such, theconnection headers include connectors that are designed to correspond todesignated terminals of the electrical device in a mating interface thatindicates a particular circuit configuration for the electrical device.

In some embodiments, the disclosed electrical devices may includeterminals that are keyed or polarized for the various circuitimplementations in which the electrical devices are employed. Forexample, the terminals may be Raster Anschluss Steck Technik (RAST)compliant connectors or another type of pitch connection plug technologyconnector. The centerline spacing of the RAST connectors may be fivemillimeters, two-and-a-half millimeters or another distance. In additionto keys, the terminals may have latch mechanisms (e.g., latches) thatmaintain the interconnection between designated terminals andcorresponding connection headers.

FIG. 1 illustrates a block diagram of an embodiment of an HVAC systemconstructed according to the principles of the disclosure. The HVACsystem 100 includes a return air duct 110, a refrigeration circuit 120,an air moving unit 130, a heat exchanger 140, a supply air duct 150, aHVAC controller 160, a first pressure switch 170 and a second pressureswitch 175. The HVAC system 100 also includes a first parallel wiringharness 180 and a second parallel wiring harness 190.

The refrigeration circuit 120 includes a compressor system 122,evaporator coils 124, and condenser coils 126 that are fluidly coupledtogether. The refrigeration circuit 120 may include multiple coolingstages. One skilled in the art will understand that the HVAC system 100may include additional components and devices that are not presentlyillustrated or discussed but are typically included in an HVAC system,such as, a power supply, an expansion valve and a condenser fan. Athermostat (not shown) is also typically employed with the HVAC system100 and used as a user interface. The various illustrated components ofthe HVAC system 100 may be contained within a single housing (e.g., acabinet). In one embodiment, the HVAC system 100 may be a rooftop unit.

The return air duct 110 and the supply air duct 150 may be conventionalducts used in common HVAC systems to receive return air and dischargeconditioned air. The refrigeration circuit 120, the air moving unit 130,the heat exchanger 140 and the HVAC controller 160 may also beconventional components that are typically employed in HVAC systems. TheHVAC controller 160 causes the air moving unit 130 to move the returnair across the evaporator coils 124 for cooling and through the heatexchanger 140 for heating to provide conditioned air for the conditionedair space. Operation of the HVAC system 100 can be controlled by theHVAC controller 160 based on inputs from various sensors of the HVACsystem 100 and from a thermostat.

The first pressure switch 170 and the second pressure switch 175 areused to determine if the air moving unit 130 has created a desired airflow through the HVAC system 100. The first and second pressure switches170, 175, may be located in the scroll of the air moving unit 130. Inother embodiments, the first and second fans 170, 175, may be located induct work of the HVAC system 100. The first pressure switch 170 isconnected to the controller 160 via the first parallel wiring harness180 and is connected to the second pressure switch 175 via the secondparallel wiring harness 190. In this embodiment, the first and secondpressure switches 170, 175, may be connected in a branch circuit. Inother embodiments, the first and second pressure switches 170, 175, canbe connected in series. The particular circuit configuration may bedetermined by a connection header that is used and that uniquelycorresponds to designated terminals which dictate the particularconfiguration of the first and second pressure switches 170, 175.

The first parallel wiring harness 180 includes a first connection header182 and a second connection header 184. The second parallel wiringharness 190 also includes a first connection header 192 and a secondconnection header 194. The first connection header 182 is configured toconnect to the controller 160 and the second connection header 184 isconfigured to connect to the first pressure switch 170. The firstconnection header 192 is configured to connect to the first pressureswitch 170 and the second connection header 194 is configured to connectto the second pressure switch 175. As such, the connection headersinclude connectors that correspond to terminals of the controller 160,the first pressure switch 170 and the second pressure switch 175. Theterminals (not illustrated) are configured to receive the correspondingconnectors. The terminals of the first and second pressure switches 170,175, include a pair of functional terminals connected across a contactthereof and a pair of jumpered terminals independent of the pair offunctional terminals and internally connected together. Each unique pairof the terminals of the first and second pressure switch 170, 175,indicate a circuit configuration for the switches 170, 175, with each ofthe terminals having a particular design that dictates a specificcorresponding connection header be used for each unique pair of theterminals.

FIG. 2 illustrates a diagram of an embodiment of a single electricaldevice employed in a circuit 200. The circuit 200 includes a printedcircuit board (PCB) 210, a parallel wiring harness 220 and an electricaldevice 230. The electrical device 230 is constructed according to theprinciples of the disclosure. In one embodiment, the circuit 200 may beemployed in a HVAC system, such as the HVAC system 100 illustrated inFIG. 1. The PCB 210 may be part of a controller of an HVAC system suchas the controller 160.

The PCB 210 includes a pair of terminals denoted as control boardterminal pair 214. The electrical device 230 also includes terminals 231including functional terminals 233 and jumpered terminals 235. Thefunctional terminals 233 are coupled across a contact of the electricaldevice 230. In this embodiment, the electrical device 230 is a switchand the functional terminals 233 are coupled across a contact indicatingthe status of the switch. The jumpered terminals 235 are internallycoupled together (i.e., connected together inside of the electricaldevice 230) via an internal jumper 239 and are not coupled to thefunctional terminals 233. The internal jumper 239 may be a conventionaljumper.

Coupled to the PCB 210 via the control board terminal pair 214 is theparallel wiring harness 220. The parallel wiring harness 220 includes afirst connection header 222 and a second connection header 224. Thefirst connection header 222 is configured to connect to the controlboard terminal pair 214. As such, the first connection header 222includes connectors 226, 227, that are designed to correspond to thecontrol board terminal pair 214. Accordingly, the control board terminalpair 214 and the first connection header 222 are paired together toprevent incorrect wiring. The second connection header 224 is configuredto connect to the functional terminals 233. As such, the secondconnection header 222 includes connectors 228, 229, that are designed tocorrespond to the functional terminals 233.

Accordingly, the functional terminals 233 and the second connectionheader 224 are paired together to prevent incorrect wiring when a singleelectrical device 230 is used. When multiple of the electrical devices230 are used in a circuit, instead of the second connection header 224,another connection header having differently configured connectors wouldbe used to correspond to one of the functional terminals 233 and one ofthe jumpered terminals 235. Another parallel wiring harness, therefore,can be used to connect the other one of the functional terminals 233 andthe other one of the jumpered terminals 235 to another one of theelectrical device.

FIG. 3 illustrates a diagram of two electrical devices as illustrated inFIG. 2 connected in series. FIG. 3 includes the PCB 210 and theelectrical device 230 including the terminals 231. FIG. 3 also includesthe same type of electrical device, 330 connected in series with theelectrical device 230. As such, the electrical device 330 includesterminals 331 including functional terminals 333 and jumpered terminals335 that are internally connected by the jumper 339. The functionalterminals 333 are coupled across a contact of the electrical device 330.

A first parallel wiring harness 320 and a second parallel wiring harness340 are illustrated. The first parallel wiring harness 320 includes afirst connection header 322 and a second connection header 324. Thefirst connection header 322 may be the same as the first connectionheader 222 of FIG. 2. The second connection header 324, however, differsfrom the second connection header 224 of FIG. 2. Instead of beingconfigured for a single switch circuit that corresponds to thefunctional terminals 233, the second connection header 324 is configuredto couple to one of the functional terminals 233 and one of the jumperedterminals 235 to allow a series connection between the electrical device230 and the electrical device 330 in a multiple switch circuit.

The second parallel wiring harness 340 then connects the electricaldevice 230 to the electrical device 330. The second parallel wiringharness 340 includes a first connection header 342 that is configured tocouple to one of the functional terminals 233 and one of the jumperedterminals 235. The second parallel wiring harness also includes a secondconnection header 344 that is configured to connect to the functionalterminals 333 of the electrical device 330. The second connection header344 may be configured the same as the second connection header 224 ofFIG. 2. As noted with respect to connection headers of FIG. 2, each ofthe connection headers of FIG. 3 include connectors that are designed tocorrespond to particular terminals. As an example, connectors 328 and329 of the connection header 324 are denoted in FIG. 3. The connectors328, 329, of the connection header 324 are configured to correspond toone of the jumpered terminals 235 and one of the functional terminals233 as illustrated in FIG. 3. In one embodiment, the correspondencetherebetween may be unique.

FIG. 4 illustrates a connection diagram of an embodiment of a singleelectrical device 430 constructed according to the principles of thedisclosure that has terminals which are keyed for designated matinginterfaces. The terminals are designed with keying feature to preventmisconnections. For example, the terminals and connection headerillustrated in FIG. 4 may be RAST compliant connectors. A single key anda single latch are denoted in FIG. 4. The keys of the terminals and thekeys of the connection headers are designed to correspond to formdesignated mating interfaces. The latches may be used to secure theconnections once coupled.

The circuit 400 includes a PCB 410, a parallel wiring harness 420 andthe electrical device 430. The electrical device 430 is constructedaccording to the principles of the disclosure. In one embodiment, thecircuit 400 may be employed in a HVAC system, such as the HVAC system100 illustrated in FIG. 1. The PCB 410 may be part of a controller of anHVAC system such as the controller 160.

The PCB 410 includes a pair of terminals denoted as control boardterminal pair 414. The electrical device 430 also includes terminals 431including functional terminals 433 and jumpered terminals 435. Thefunctional terminals 433 (denoted as terminals 2 and 3 of the terminals431) are coupled across a contact of the electrical device 430. In thisembodiment, the electrical device 430 is a switch and the functionalterminals 433 are coupled across a contact indicating the status of theswitch. The jumpered terminals 435 (denoted as terminals 1 and 4 of theterminals 431) are internally coupled together via an internal jumper439 and are not coupled to the functional terminals 433.

Coupled to the PCB 410 via the control board terminal pair 414 is theparallel wiring harness 420. The parallel wiring harness 420 includes afirst connection header 422 and a second connection header 424. Thefirst connection header 422 is configured to connect to the controlboard terminal pair 414. As such, the first connection header 422includes connectors 426, 427, that are keyed to correspond to thecontrol board terminal pair 414. Accordingly, the control board terminalpair 414 and the first connection header 422 are paired together as adesignated mating interface to prevent incorrect wiring. The secondconnection header 424 is configured to connect to the functionalterminals 433. As such, the second connection header 422 includesconnectors 428, 429, that are keyed to correspond to the functionalterminals 433. Accordingly, the functional terminals 433 and the secondconnection header 424 are paired together as a designated matinginterface to prevent incorrect wiring when a single electrical device430 is used. When multiple of the electrical devices 430 are used in acircuit, a different connection header is needed instead of the secondconnection header 424 to correspond to one of the functional terminals433 and one of the jumpered terminals 435. Another parallel wiringharness can then be used to connect the other one of the functionalterminals 433 and the other one of the jumpered terminals 435 to anotherone of the electrical device.

FIG. 5 illustrates a connection diagram of a circuit configuration 500having two of the electrical devices of FIG. 4 coupled in series. FIG. 5includes the PCB 410 and the electrical device 430 including theterminals 431. FIG. 5 also includes the same type of electrical device,530 connected in series with the electrical device 430. As such, theelectrical device 530 has terminals 531 including functional terminals533 and jumpered terminals 535 that are internally connected by aninternal jumper 539. The functional terminals 533 are coupled across acontact of the electrical device 530. A single key and latch areidentified in FIG. 5.

A first parallel wiring harness 520 and a second parallel wiring harness540 are illustrated. The first parallel wiring harness 520 includes afirst connection header 522 and a second connection header 524. Thefirst connection header 522 may be the same as the first connectionheader 422 of FIG. 4. The second connection header 524, however, differsfrom the second connection header 424 of FIG. 4. Instead of beingconfigured for a single connection that corresponds to the functionalterminals 433, the second connection header 524 is configured to coupleto terminal “1” of the functional terminals 433 and terminal “2” of thejumpered terminals 435 to signify a series connection between theelectrical device 430 and the electrical device 530.

The second parallel wiring harness 540 then connects the electricaldevice 430 to the electrical device 530. The second parallel wiringharness 540 includes a first connection header 542 that is configured tocouple to terminal “3” of the functional terminals 433 and terminal “4”of the jumpered terminals 435. The second parallel wiring harness 540also includes a second connection header 544 that is configured toconnect to the functional terminals 533 of the electrical device 530.The second connection header 544 may be configured the same as thesecond connection header 424 of FIG. 2.

As noted with respect to connection headers of FIG. 4, each of theconnection headers of FIG. 5 include connectors that are designed tocorrespond to particular terminals. As an example, connectors 528 and529 of the connection header 524 are denoted in FIG. 5. The connectors528, 529, of the connection header 524 are configured to correspond toone of the jumpered terminals 435, terminal “1,” and one of thefunctional terminals 433, terminal “2,” as illustrated in FIG. 5. In oneembodiment, the correspondence therebetween may be unique.

FIGS. 6A, 6B and 6C illustrate schematic diagrams of another embodimentof an electrical device 600 constructed according to the principles ofthe disclosure. The electrical device 600 is a switch. One skilled inthe art will understand that the electrical device may be another devicebesides a switch. The electrical device 600 has multiple terminalsincluding a pair of functional terminals 602, a pair of jumperedterminals 604 and a common terminal 605. The functional terminals 602are coupled across a contact of the electrical device 600. The jumperedterminals 604 are independent of the functional terminals 602 and areinternally connected together inside the electrical device 600. Thecommon terminal 605 is independent of the jumpered terminals 604 and isinternally connected to the common terminal of the switch. The internaljumpers are denoted in FIG. 6A as jumper 607 and jumper 609.

FIGS. 6A, 6B and 6C represent the electrical device 600 in differentcircuit configurations. In each drawing, the electrical device 600 maybe coupled, via a parallel wiring harness, to a control board tocomplete the circuit configurations. The various parallel wiringharnesses include cables that can be coupled to a common terminal(represented by “c” in the FIGS. 6A, 6B and 6C) and return cables thatcan be coupled to designated terminals on the control board. Theconnection headers for connecting to the control board are notillustrated in FIG. 6A, 6B or 6C. The various connection headersillustrated in FIGS. 6A, 6B and 6C may be configured similarly to theconnection headers in the preceding figures.

In FIG. 6A, the electrical device 600 is connected to a single parallelwiring harness 610 representing when a single electrical device 600 isin a single switch circuit. The parallel wiring harness 610 includes aconnection header 612 and cables 614. The connection header 612 includesconnectors that are configured to connect to the functional terminals602.

In FIG. 6B, the electrical device 600 is connected to a secondelectrical device 680 in series. Accordingly, the electrical device 680has multiple terminals including a pair of functional terminals 682, apair of jumpered terminals 684 and a common terminal 685. In thisconfiguration, two parallel wiring harnesses are used. A first parallelwiring harness 620 includes a connection header 622 and cables 624. Asecond parallel wiring harness 630 includes a first connection header632, cables 634 and a second connection header 636. The connectionheader 622 includes connectors that are configured to connect to one ofthe functional terminals 602 and one of the jumpered terminals 604. Theconnection header 632 includes connectors that are configured to connectto one of the jumpered terminals 604 and the common terminal 605. Theconnection header 636 includes connectors that are configured to connectto the functional terminals 682.

In FIG. 6C, the electrical device 600 is connected to the secondelectrical device 680 as a branch circuit. In this configuration, twoparallel wiring harnesses are also used. A first parallel wiring harness640 includes a connection header 642 and cables 644. For the branchconnection, the parallel wiring harness 640 includes three cablesinclude a common cable and return cables from two switches. With adedicated cable for each switch, the status of a particular switch canbe determined, by, for example, a HVAC controller. The second parallelwiring harness in FIG. 6C may be the parallel wiring harness 630 of FIG.6B. The connection header 642 includes connectors that are configured toconnect to the functional terminals 602 and one of the jumperedterminals 604.

FIG. 7A illustrates schematic diagrams of different circuitconfigurations having electrical devices. The electrical device ordevices in FIG. 7A is a switch. In other embodiments, the electricaldevice or devices may be another type of device. Four different types ofcircuits employing a switch are illustrated in a normally open andnormally closed condition. The four types of circuits are a singleswitch, a series circuit, a parallel circuit and a branch circuit. Acommon terminal (C) and the various switch terminals (SW, SW1 and SW2)are illustrated in FIG. 7A along with the condition of the switches.

FIGS. 7B, 7C and 7D illustrate schematic diagrams of embodiments ofswitches constructed according to the principles of the disclosure thatmay be employed in the various circuit configurations of FIG. 7A. InFIG. 7B a switch 710 is illustrated. The switch 710 corresponds to theelectrical device 230 of FIG. 2. In FIG. 7B, the switch 710 is connectedin a single switch circuit and in a series circuit. Parallel wiringharnesses may be used to couple the switch 710 to form the variouscircuit configurations.

In FIG. 7C, another switch 720 is illustrated. Unlike switch 710, switch720 includes six terminals and three different internal jumpers. Thedifferent internal jumpers allows the switch 720 to be used as a singledevice and to be coupled in series or parallel. As with switch 710,parallel wiring harnesses can be used to couple the switch 720 in thedifferent configurations.

In FIG. 7D, yet another switch 730 is illustrated. The switch 730 alsoincludes six terminals and multiple internal jumpers. Unlike switch 720,the switch 730 has internal jumpers that allow it to be employed as asingle device, in a series circuit, a parallel circuit and a branchcircuit. Parallel wiring harnesses may also be employed with the switch730 to form the various circuit configurations. The parallel wiringharnesses employed with the switches 710, 720 and 730 may be similarlyconfigured as the parallel wiring harnesses previously discussed herein.While switch 710 includes four terminals, switches 720 and 730 includesix terminals. Switch 710 includes a pair of functional terminals and apair of jumpered terminals. Switches 720 and 730 also include a pair offunctional terminals and a pair of jumpered terminals. Additionally,switches 720 and 730 include other terminals that are each internallyjumpered to one of the functional terminals.

FIG. 8 illustrates a flow diagram of an embodiment of a method 800 ofmanufacturing a HVAC unit according to the principles of the disclosure.The HVAC unit may be a rooftop unit. The method begins in a 805.

In a step 810, a HVAC controller is connected to a first switchemploying a parallel wiring harness. The first switch includes multipleterminals including functional terminals and jumpered terminals that areindependent of the functional terminals. The functional terminals arecoupled across the switching component of the switch and can be used toindicate the status of the switch (e.g., open or closed). The jumperedterminals are internally connected within the switch. In someembodiments, the first switch may include an additional terminal that isinternally connected to one of the functional terminals. Designatedcombinations of the terminals indicate a circuit configuration for theswitch in the HVAC unit. A designated combination may be a pair of theterminals or even three of the terminals. Each of the terminals of thefirst switch have a particular design that dictates a specificcorresponding connection header be used for each of the designatedcombinations.

In a step 820, the first switch is connected to a second switchemploying another parallel wiring harness. The second switch is the sametype of switch as the first switch. The first switch may be coupled tothe second switch in series or in a branch circuit. The same switch,therefore, can be used for different circuit configurations, includingbeing used singularly, for a series connection or a branch connection.The method 800 then ends in a step 830.

The devices disclosed herein include terminals with internal jumpersthat allow parallel harnesses to be used with the device in multiplecircuit configurations. The sequence of the jumpered terminals relativeto the other terminals of the device is designed for particular circuitconfigurations. A certain sequence is needed for the parallel wiringharnesses to function properly as desired. The terminals are positionedfor a single connector position to be used when a single device circuitis implemented. Other positions may be used for series, branch orparallel circuit configurations.

Those skilled in the art to which this application relates willappreciate that other and further additions, deletions, substitutionsand modifications may be made to the described embodiments.

What is claims:
 1. A system comprising: a controller; a parallel wiringharness comprising a first connection header and a second connectionheader, wherein the first connection header is interoperably coupled tothe controller; a first electrical device comprising a plurality ofterminals; wherein each terminal of the plurality of terminalscomprises: a plurality of functional terminals; a plurality of jumperedterminals; and wherein designated combinations of the plurality ofterminals specify a circuit configuration for employing the firstelectrical device in the system with each of the plurality of terminalshaving a particular design that dictates a specific correspondingconnection header be used for each of the designated combinations. 2.The system of claim 1, wherein a single one of the designatedcombinations of the plurality of terminals corresponds to the secondconnection header.
 3. The system of claim 1, wherein the plurality ofjumpered terminals are independent of the plurality of functionalterminals.
 4. The system of claim 1, wherein the plurality of jumperedterminals and the plurality of functional terminals are internallyconnected within the first electrical device.
 5. The system of claim 1,wherein the system comprises a Heating, Ventilating and Air Conditioning(HVAC) system.
 6. The system of claim 1, wherein the first electricaldevice comprises at least one of a limit switch and a pressure switch.7. The system of claim 1, wherein at least one terminal of the pluralityof terminals comprises a common terminal that is internally connected toat least one of the plurality functional terminal.
 8. The system ofclaim 1, wherein the circuit configuration indicates that the firstelectrical device is connected to a second electrical device in series.9. The system of claim 1, wherein the circuit configuration indicatesthat the first electrical device is connected to a second electricaldevice in parallel.
 10. The system of claim 1, wherein the firstconnection header is coupled to terminals of the controller.
 11. Anelectrical device comprising: a contact; a plurality of terminalscoupled to the contact, wherein each terminal of the plurality ofterminals comprises: a plurality of functional terminals connectedacross the contact; a plurality of jumpered terminals; and whereindesignated combinations of the plurality of terminals specify a circuitconfiguration for the electrical device with each of the plurality ofterminals having a particular design that dictates a specificcorresponding connection header be used for each of the designatedcombinations.
 12. The electrical device of claim 11, wherein the contactis configured to indicate a status of the electrical device.
 13. Theelectrical device of claim 11, wherein the electrical device comprisesat least one of a limit switch and a pressure switch.
 14. The electricaldevice of claim 11, wherein the plurality of jumpered terminals areindependent of the plurality of functional terminals.
 15. The electricaldevice of claim 11, wherein the plurality of jumpered terminals and theplurality of functional terminals are internally connected within theelectrical device.
 16. The electrical device of claim 11, wherein thecircuit configuration indicates that the electrical device is connectedto another electrical device in series.
 17. The electrical device ofclaim 11, wherein the circuit configuration indicates that theelectrical device is connected to another electrical device in parallel.18. The electrical device of claim 11, wherein the electrical device isoperable within a Heating, Ventilating and Air Conditioning (HVAC)system.